ES1300508U - Multiplier for the initiation of blasting of bulk explosives (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Multiplier for the initiation of blasting of bulk explosives (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

Multiplier for the initiation of blasting of bulk explosives

field of invention

The present invention is directed to a booster intended to be used for the initiation of blasting of bulk explosives.

Background of the invention

The use of an explosive charge for a blast involves the introduction of a mass of explosive material into a hole (hole made in a rock or other material to be blown up, which is filled with explosive material) for its subsequent explosion. Thus, the explosive charge can be, for example, stored in cartridges, and the cartridges of explosive material are fitted to the walls of the hole. In the state of the art, explosive charges are known that comprise a single type of explosive in the entire hole (single charge), or alternatively, explosive charges that first have a denser and more powerful explosive (bottom charge) and then a less explosive. dense (column charge) covering the bottom charge.

The continuous growth in the demand for minerals and metals during the last decades has caused a huge increase in the consumption of explosives. To meet the demand for explosives, the market has evolved from packaged explosives to bulk explosives that are transported, sensitized, and delivered into mine blastholes by assembled facilities in mobile units or trucks. The manufacture of bulk explosives began in the 1950s with the introduction of ANFO (ammonium nitrate and fuel mixtures), followed in the 1960s-70s with slurries, aqueous gels (hydrogels) and emulsions and today over 90 % of all explosives consumed are supplied in bulk form. The use of bulk explosives improves the coupling between the rock and the explosive material, allowing an optimization of the blasting with respect to the perforation carried out.

Explosive multipliers (also called boosters) are high-power explosive charges that are used to initiate other explosives with low detonation sensitivity, such as bulk explosives. In general, the multipliers are explosive that present a high density, power, velocity and pressure of detonation. In turn, the multipliers must be initiated with detonators. Conventional detonators include, for example, non-electric detonators, electric detonators and electronic detonators.

Current boosters are generally produced by casting molten high explosives (for example, pentolite, composition B) into cylindrical, cardboard, or more robust (for example, plastic) casings, and have at least one through cavity. and a blind cavity to house the detonator. The detonator, usually cylindrical in shape, and which can have different types of electrical cables or a plastic tube for its activation, is passed through the through cavity and then completely inserted into the blind cavity. In this way, the detonator is housed in the blind cavity and the tubes or cables of the detonators pass through the through cavity, thus being protected from certain frictions or impacts that the container (or body) of the multiplier may suffer during charging. in the bore An example of this multiplier configuration comprising a blind cavity and a through cavity is found in the European patent application EP 3 392601 A1.

Typically, the blind cavity and the through cavity have a similar diameter and both are located in the central area of the multiplier, parallel to its longitudinal axis, that is, in the space intended to house the explosive charge.

The multiplier assembly, which includes the multiplier, the detonator and its cables or tubes, is then inserted into a borehole.

However, there is still a need to develop new multipliers whose design allows improving the performance of existing multipliers in the state of the art.

Summary of the invention

The through cavity of the multipliers of the state of the art is very useful since it constitutes a protection conduit for the tubes or cables of the detonators and at the same time serves to center said multiplier. However, the inventors of the present invention have observed that the location of the through cavity in the central area of the explosive charge, as occurs in current multipliers, is unfavorable.

In particular, the presence of an empty hole as the through cavity in the container (also referred to as body) of the multiplier contributes to generating rarefactions, which are traction waves by reflection of the detonation wave in the empty holes. Said rarefactions are generated precisely in an area of the explosive charge, the geometric axis or an area close to it, in which the detonation front should have its maximum performance (hydrodynamic theory of explosives). Therefore, the action of those rarefactions generated by reflection in the central through cavity gives rise to worse performance of the multiplier.

The present invention proposes a solution to the problem of low multiplier performance due to rarefactions (which are pressure waves of negative value) by providing a multiplier according to claim 1 and a multiplier assembly according to claim 29. The dependent claims define preferred embodiments of the invention.

A first inventive aspect provides a multiplier for blasting bulk explosives comprising:

- a container adapted to house an explosive charge; and

- a detonator cap for closing said container comprising at least one blind cavity adapted to accommodate at least one detonator of the multiplier, the detonator comprising connection cables or tubes;

- an explosive charge housed in the container;

where

- the container comprises at least one lateral groove adapted to house the cables or tubes of the at least one booster detonator, wherein said at least one lateral groove comprises one or more tabs adapted to retain cables or tubes of the at least one booster detonator ;

- the at least one lateral groove is arranged on an external surface of the container; and

- the container is adapted to cooperate with the stopper, housing said stopper inside it.

In the multiplier of the invention, the closure of the container with the cap is hermetic, which advantageously prevents water or humidity from entering and damaging the explosive charge.

In the context of the present invention, the flanges of the grooves shall be understood as protrusions, flaps, flaps or the like that protrude from the groove(s) configured to facilitate retention in the lateral grooves of the cables/tubes of the cables. detonators.

The multiplier according to the present invention solves the problem of such rarefactions by providing a multiplier which lacks a central through-bore and instead has lateral grooves through the external surface of the multiplier. Said grooves act as retaining and accommodation means, and allow proper protection of the detonator cables or tubes, while freeing the container from empty spaces, which is precisely where the most negative rarefactions occur.

As an advantage over the state of the art, the replacement of the central through-hole of the multiplier by lateral grooves to guide the cables/tubes of the detonators allows for a central section of the container "clearer" of elements, which facilitates the industrial process. In particular, the filling operation with the explosive charge is simpler, for example by conventional industrial means of extrusion, drawing or casting.

Advantageously, the absence of the central through-hole cavity prevents there being empty holes, which in turn prevents the generation of rarefactions, which reduce the performance of the multipliers.

Advantageously, the grooves arranged on the external surface of the container make it possible to define lateral ducts that allow the tubes or cables of the detonators to be housed and retained, allowing the tubes or cables to be fixed without occupying the central part of the body of the multiplier. These lateral grooves are not through. The size of these grooves (length, thickness) will be determined by the size of the tubes or cables of the multiplier detonators that must be housed in them in a tight manner (for example, by mere application of pressure), without requiring the presence of additional joining means (staples, etc.). Groove tabs help retain tubing or cables.

Additionally, the existence of grooves on the external surface of the container and the plug facilitates handling of the multiplier during manufacturing. For example, the grooves make it easier for a robotic arm or other automated means of positioning to pick up the multiplier, fill it with explosive charge and process it properly (packaging, storage, etc.).

In the context of this invention, the term "cavity" should be interpreted as a perforation or hole. The cavities can be "through" or "blind", depending on whether or not they completely go through the element to which they refer, respectively. A through cavity has an entry orifice and another exit orifice, while a blind cavity only has a single inlet orifice.Preferably, these cavities are substantially parallel to the longitudinal axis of the multiplier, in the case in which it is cylindrical or prismatic.

Likewise, the "container" will comprise a volume adapted to house the explosive charge and the detonator plug inside.

In a preferred embodiment, the container of the invention comprises: a substantially elongated main body defining a longitudinal axis; and a mouth, located at a first end of the main body of the container, through which the plug is introduced into said main body, said mouth being adapted to receive the plug in a tight fit, sealing the container.

In the context of this invention, it will be understood that a connection between the stopper and the container is "tight" when it is ensured in such a way that it prevents its detachment or separation, so that both parts (cap and container) cooperate with each other. In some embodiments of the invention, the tight fit can be achieved, for example, by inserting at least part of the stopper, applying mechanical pressure, into the container because a contour or perimeter of the stopper is slightly larger than the contour of the container. To achieve a tight union they can be by threading, screwing, riveting, or by means of adhesives.

Likewise, in the context of the invention, it will be understood that a closure is hermetic when it does not allow any type of fluid to pass into the interior of the multiplier container.

Advantageously, the cap is housed inside the container, closing the assembly and protecting the explosive charge from the elements.

Hereinafter, the "detonator cap" (or simply, "cap", as it will also be called hereinafter) will refer to an element adapted to close the container, as well as to house the one or more detonators of the multiplier to be will be in charge of initiating the detonation of the multiplier. The plug comprises a substantially flat surface and the blind cavity/cavities for housing the detonators.

The container of the multiplier of the present invention comprises an "external surface", which remains in contact with a hole in which said multiplier is introduced, and an "internal surface" which remains in contact with the explosive charge that is housed in the container. In this way, it is the outer surface that remains close to or in contact with the material or part to be blown up (for example, an explosive that is initiated by the multiplier) when the multiplier of the invention is in operational condition.

In a preferred embodiment, the multiplier container additionally comprises holding means configured to cooperate with multiplier handling means configured to raise or lower the multiplier in a borehole.

In an even more preferred embodiment, the fastening means are located at a second end of the main body of the container, longitudinally opposite the first end where the mouth of said container is located.

In certain specific embodiments of the booster of the invention, the holding means of the container comprise an opening or handle (as a handle), and the handling means of the booster comprise a rope that is adapted to pass through said opening or handle. In an alternative embodiment of the multiplier of the invention, the detonator cables or tubes themselves can perform this function of handling means.

Advantageously, the opening or handle of the container functions as a hook at its distal end with respect to the mouth of the container where the stopper is inserted (ie, the handle is located at the second end of the container). Once the cables or tubes of the detonator or detonators have been attached, this hook is used to unhook the multiplier in the blastholes, or to hoist it in the event that it is necessary to extract it.

In a more preferred embodiment, the container and the stopper act respectively as female and male at the junction of both elements.

In another preferred embodiment, in an operative position of the multiplier, the stopper is completely included in the main body. Once the container and the stopper are attached, the stopper is completely within the volume of the container. That is, the cap does not protrude from the container.

In the context of this invention, "operating position" is understood to mean the closed position when the tube and container have been coupled.

In some preferred embodiments, the stopper and the mouth of the container comprise one or more recesses and/or projections complementary to each other. Advantageously, this strengthens the bond between the stopper and the container. This configuration is carried out in order to increase the hermeticity of the assembly and thus protect the explosive charge housed in the container from the action of water or humidity contained in the holes, or from other environmental conditions that degrade the performance of the multiplier.

The multiplier of the invention can take on different geometric shapes, which is mainly determined by the geometric shape of the container. The geometric shape for the manufacture of the multiplier of the invention can be any polyhedron, more preferably, a prism or a cylinder. In the context of this invention, the definition of "cylinder" will include both those where the bases are circles and those where the bases are ellipses, ellipsoids or other rounded shapes.

In a particular embodiment, the multiplier has a cylindrical or prismatic shape. The shape of the multiplier is substantially given by the shape of the container, since the cap is housed inside it once the multiplier is in the operative position. In a preferred embodiment, the multiplier has a cylindrical shape, said cylinder preferably having a circular and straight base.

Advantageously, the cylindrical shape, and in particular the right circular cylinder, allows the multiplier to be used in holes of the same configuration, which in practice is one of the most common.

In a more preferred embodiment, the multiplier has a cylindrical shape with its two ends in the form of a truncated cone, so that the diameter of the container is smaller at the ends with respect to the middle part of it.

In some preferred embodiments, both the container and the plug are made of a rigid material. In certain even more preferred embodiments, the rigid material comprises a plastic material, such as polystyrene and/or polyethylene, more specifically medium-density polyethylene, which is a thermoplastic with a density range of 0.926-0.940 g/cm3, which balances the properties of high-density and low-density polyethylene, being less dense but more resistant to stress cracking than the former, and more rigid than the latter.

In one embodiment, the container and the plug are of the same material. In another embodiment, the container and the cap are of different material. In a particular embodiment, the container is made of polyethylene (preferably medium density polyethylene) and the cap is made of polystyrene.

The multiplier can be designed with different dimensions. As previously indicated, the stopper is preferably fully contained within the volume of the container. In such a case, the external dimensions of the multiplier and the container are the same, in particular, the diameter of the mouth of the container is substantially equal to the diameter of the stopper, so as to facilitate their joining or snug fitting together.

In some preferred embodiments, the container has a total length between 15 and 50 cm, and even more preferably, between 15 and 20 cm. In a particular embodiment, the total length of the container is approximately 18 cm.

In certain embodiments of the booster, the space reserved in the container to accommodate the explosive charge has a length of between 10 and 40 cm, for example approximately 13 or 14 cm.

In certain embodiments of the multiplier, the diameter of the container is between 40 and 200 mm, more preferably between 50 and 90 mm. In the context of this invention, the diameter of the container will be interpreted as the dimension in the direction perpendicular to the longitudinal axis defined by the container.

In the multiplier of the invention, the diameter of the multiplier can be changed with respect to to the hole, for the same length, in order to optimize the design. It should be noted that the larger the diameter of the multiplier, the better it couples to the hole and therefore provides a greater detonation propagation speed.

In a preferred embodiment of the invention, the grooves have a non-uniform thickness, tapering as they approach the mouth of the container. For example, the grooves may become progressively narrower as they approach the mouth of the container in order to facilitate retention of the detonator wires or tubes.

In a particular embodiment, the booster comprises a single blind cavity adapted to house a booster detonator.

In an even more preferred embodiment, the multiplier comprises exactly two blind cavities. According to this last configuration, when the detonator cap includes two blind cavities, it is possible to use the multiplier with a detonator, leaving one blind cavity occupied with said detonator and the other blind cavity free; or with two detonators, each of which would occupy a blind cavity.

Advantageously, including two blind cavities allows two detonators to be introduced into the multiplier, in those cases in which a second detonator is required to start the multiplier.

In addition, the use of two shorter blind cavities (instead of a single longer central cavity or conduit, this "greater length" being understood as the cavity traversing the entire length of the main body) frees the part from cavities. center of the multiplier container, minimizing rarefactions.

In other embodiments of the present invention, the possibility of incorporating more than two blind cavities in the multiplier is also contemplated, and therefore, the possibility of using more than two detonators.

In a particular embodiment, the plug of the multiplier comprises one or two blind cavities.

In certain embodiments of the multiplier, the lateral grooves are substantially parallel to the longitudinal axis of the container.

In the multiplier of the invention, the blind cavities or holes are perforations that start in the central zone of a substantially flat surface of the plug of the multiplier and extend perpendicular or substantially perpendicular to said plug. As used herein "substantially perpendicular" shall be interpreted as an orientation that makes an angle of more than 45 degrees with respect to the reference axis or plane, preferably 60 or more degrees, more preferably 80 or more degrees and still more preferably about 90 degrees.

In this way, once the container is closed with the stopper and loaded with the explosive charge, the blind cavity or cavities extend through the explosive charge in the central area of the multiplier, parallel or substantially parallel to the longitudinal axis of the multiplier. and without completely traversing the length of the multiplier body. As used herein "substantially parallel" shall be interpreted as an orientation that makes an angle of less than 45 degrees with respect to the reference axis or plane, preferably 30 degrees or less, more preferably less than 10 degrees and still more preferably about 0 degrees.

In certain embodiments of the booster, the at least one blind cavity has a substantially cylindrical shape, thus conforming to the shape of conventional detonators.

In some embodiments, the length of the at least one blind cavity is in the range of 90 to 110 mm, preferably approximately 100 mm. In other embodiments, the diameter of the blind cavity(es) can vary along its longitudinal axis.

In one embodiment, the diameter of the at least one blind cavity of the multiplier is non-uniform. In an even more particular embodiment, the entry point (opening) of the blind cavity has a diameter of approximately 9 mm and the final part (blind end) has a diameter of approximately 8 mm. Said diameter reduction may be gradual along the entire longitudinal axis and/or there may be one or more areas in which the diameter reduction is more pronounced.

Advantageously, the lateral grooves made on the outer surface of the multiplier container replace the typical central through-passing duct in the central area of the explosive charge, which is unique and larger in conventional multipliers.

In a particular embodiment, the mouth of the container comprises one or more notches. In a more particular embodiment, the mouth of the container comprises two lateral notches, at diametrically opposite ends of said mouth of the container.

Advantageously, the notches in the mouth of the container facilitate the placement of the detonator tubes or wires.

In a more particular embodiment, the container further comprises one, two or more lateral grooves, parallel or substantially parallel to its longitudinal axis and arranged on the external surface of the main body of said container. In these embodiments, the mouth of the container has as many notches as there are grooves, said grooves being respectively aligned with one of the grooves.

In some embodiments of the multiplier, the side grooves extend the full length of the container.

In other alternative embodiments, the side grooves extend only partially along the length of the container.

In a preferred embodiment, the explosive charge of the booster comprises extruded or drawn explosives. Even more preferably, said explosive charge is dynamite. Advantageously, the multiplier of the invention is particularly useful for this type of explosive charges, since it allows the container to be filled easily.

In summary, the multiplier of the invention solves the problem of rarefactions in the central hole (main body) of the multiplier by transferring this necessary protection conduit to the external surface of the side walls of the container, thus transforming a single central conduit of larger size, into at least two smaller ducts. The grooves or lateral ducts are strategically designed and located to secure and protect the detonator tubes or cables, while freeing the central core of the multiplier container from holes, which is precisely where the most negative rarefactions occur. . Thus, the size of the grooves is adapted so that the tubes and cables of the multiplier enter and are fixed by pressure. In this way, it is avoided having the through hole.

A second inventive aspect of the present invention refers to a multiplier assembly, comprising:

- a multiplier according to any of the previously described embodiments; - at least one detonator configured to be housed in at least one of the blind cavities;

- Detonator cables or tubes configured to be housed, tightly, in the at least one lateral groove of the container.

The multiplier assembly of the invention is particularly useful for its use as an explosive multiplier, which is understood as a powerful charge with a cylindrical section, and clearly uncoupled with the hole, so that it is embedded within the bulk explosive that it intends to initiate. . However, the invention could also be configured to perform as full bottom charges (adapting its dimensions so that it is much more coupled to the diameter of the drilled holes) or as full column charge (extending somewhat more the decoupling of the charge with respect to the drilled holes). to the bore).

In summary, the invention provides a multiplier and multiplier assembly for the initiation of blasting of bulk explosives, which provides a different solution to the current concept of initiation by means of a conventional pentolite multiplier. However, this solution can also be complementary to the usual pentolite priming.

All features of the invention described herein (including the claims, description, and figures) may be combined in any combination, except for mutually exclusive combinations of such features.

Description of the figures

These and other features and advantages of the invention will become clearer from the following detailed description of a preferred embodiment, given solely by way of illustrative and non-limiting example, with reference to the accompanying figures. .

Figure 1 This figure shows a detonator cap, according to a possible embodiment of the multiplier of the invention.

Figure 2 In this figure additional views of the cap of Figure 1 are presented.

Figures 3A, 3B These figures show a container according to a possible embodiment of the multiplier of the invention, adapted to accommodate the cap of Figures 1-2, where two lateral grooves are arranged that extend only partially along the entire length of the container.

Figure 4 This figure shows a plan view of the container of Figure 3 and a sectional view of section B-B of Figure 3A a).

Figure 5 This figure shows a representation of the assembled multiplier, where it can be seen how the plug of Figures 1-2 is inserted into the main body of the container illustrated in Figures 3-4.

Figure 6 This figure shows a representation of two positions of the multiplier of Figure 5: open (uncoupling cap and container) and closed (coupling cap and container).

Figure 7 This figure shows a detail of the retention of the detonator cables or tubes in the grooves, thanks to the tabs.

Figure 8 This figure represents a section of the multiplier according to another alternative embodiment of the present invention, with a single blind cavity in the detonator cap, and where the lateral grooves extend along the entire length of the container (including the mouth ).

Figure 9 Figure 9 shows various views of the multiplier according to another alternative embodiment of the present invention, with two blind cavities in the detonator cap, and where the lateral grooves extend along the entire length of the container (including the mouth).

In the previous figures, the numerical references that are collected in the following table are used.

Detailed description of the invention

The accompanying drawings, which are incorporated into and form a part of this specification, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the multiplier (1) of the invention. These embodiments should be interpreted as illustrative, not limiting, of possible preferred implementations of the invention. Unless otherwise indicated, drawings may not be to scale.

A first preferred embodiment of the invention refers to a multiplier (1) comprising a detonator cap (2) (or simply "cap", as it will be referred to from here on) and a container (3). Figures 1 and 2 they correspond to a merely illustrative embodiment of the detonator cap (2) for the multiplier (1) according to the present invention For simplicity, the detonators have not been represented in the figures.

In particular, Fig. 1(a) comprises a top view of the cap (2), while Fig. 1(b) corresponds to a side view of said cap (2) according to section AA represented in Fig. 1 (to). A three-dimensional view of the appearance of the plug (2) is shown in Fig. 1(c), where it can be seen that said plug (2) comprises two blind cavities (2.1, 2.2), which allow the introduction of detonators therein. Likewise, as is also observed in Fig. 1(c), the blind cavities (2.1, 2.2) have a circular section; however, they may have a different geometry in other embodiments.

The cap (2) of Fig. 1 is made of polystyrene and is adapted to be inserted into a main body (3.1) of the container (3) of the multiplier (1) of the invention, which will be shown later in Fig. 3.

Fig.2 comprises an enlarged view of the details Z, Y and X indicated in Fig. 1(b), respectively represented in Fig. 2(a), 2(b) and 2(c). It should be noted that the plug in Fig.2 includes two blind cavities (2.1,2.2) for the use of the multiplier with two detonators. In one embodiment the detonators are different. In another embodiment the detonators are the same.

On the other hand, Figures 3-4 correspond to a preferred embodiment of the container (3) for the multiplier (1) according to the present invention. In particular, in Fig. 3A(a) a longitudinal section (section A-A) illustrates the container (3) of the invention, made of substantially rigid material, while Fig. 3A(b) illustrates the longitudinal section (section A-A , rotated 90° with respect to Fig. 3A (a)) of said container (3). The container (3) comprises a main body (3.1) where an explosive charge is housed, a mouth (3.2) and a handle (3.3). A three-dimensional representation of the container (3) is shown in Fig.3B, where two grooves (3.4, 3.5) can be clearly seen in the main body (3.1): a first groove (3.4) at the second end, at the proximal end of the container (3) with respect to the handle (the first groove (3.4) ends in the handle (3.3)); and a second groove (3.5) at an intermediate point between the two ends of the main body (3.1). However, in other embodiments of the invention a greater number of grooves can be arranged along the outer surface of the main body (3.1) of the container. The grooves (3.4, 3.5) are arranged on the outer surface of the main body (3.1), spaced apart, substantially aligned with each other and only partially occupying its length.

On the other hand, the mouth (3.2) comprises two notches (3.6), one of which corresponds to detail Y of Fig. 3A(b) arranged on its contour. These notches (3.6) are substantially shorter than the lateral grooves (3.4, 3.5) of the container (3).

Fig. 4 corresponds to section BB previously shown in Fig. 3A(a). In particular, Fig. 4(a) is a view from the first end of the container (3) in which detail Z can be seen, while Fig. 4(c) is a view from the second end (proximal end to the handle (3.3)). The Figs. 4(b) and 4(c) show detailed views of details Z and Y (notches (3.6) shown in Figures 4(a) and 3(b) respectively). In Fig. 4(a) it can be seen that the mouth (3.2) of the container (3) comprises two lateral notches (3.6), at diametrically opposite ends of said mouth (3.2), which are preferably arranged in a straight line between them from A cross-sectional perspective of the container.

The container (3) is adapted to cooperate with the plug (2) illustrated above in Figures 1-2, housing said plug (2) inside it. In particular, the cap (2) shown in Figs. 1 and 2 is designed to be directly pressed into the container (3) of Figs. 3-4, so that once inserted it is fully housed inside the container (3). In this way, when the multiplier (1) is inserted into the bottom of a hole, the multiplier (1) hangs directly from handling means (either external ropes, or the detonator tubes or cables, etc.) that they are seized or secured in the handle (3.3) of the second end of the container (3). For example, using the detonator's own tubes or cables as a handling means, the multiplier (1) can be lowered in a borehole. As can be seen, in this particular embodiment, the container (3) is substantially cylindrical.

Figures 5-6 correspond to the multiplier (1) once assembled, formed by the plug (2) of Figures 1-2 and the tube (3) of Figures 3-4. Specifically, Fig. 5 shows different views of the multiplier (1) assembled, where it can be seen how the detonator cap (2) is housed inside the container (3) made of rigid material, see for example Fig. 5 ( b), where the body (3.1) has been made transparent to see how the plug (2) looks inside. In this particular embodiment, the plug (2) comprises two blind cavities (2.1, 2.2), which are adapted to receive respective detonators (not shown in the figure). As can be seen, in this case the blind cavities (2.1, 2.2) do not extend along the entire length of the container (3). In particular, the stopper (2) is made of polystyrene, while the initiator rigid tube is made of polyethylene.

Fig. 6 shows two positions of the multiplier assembly of Fig. 5: open (uncoupling the cap (2) and the container (3)) and closed (inserting the cap (2) in the container (3), that is, in operative position for the use of the multiplier). The axis E is the longitudinal axis defined by the main direction of the container (3).

In Fig. 7 multiple tabs (3.8) can be seen in a groove (3.7) that extends completely along the entire main body (3.1), which allow the cables or tubes of the multiplier (1) to be tightly retained.

In other embodiments of the invention, these one or more tabs (3.8) are found both in the first lateral groove (3.4) and in the second lateral groove (3.5).

Fig. 8(a) represents a particular embodiment of the plug (2) for an embodiment of the multiplier (1) according to the present invention, which has a single blind cavity (2.1) made on the surface (2.3) of said plug. . Fig. 8(b) represents the container (3) of the multiplier (1) in which the plug (2) of Fig. 8(a) is inserted. As can be seen, in this case the length of the blind cavity (2.1) is less than the length of the main body (3.1). The plug (2) is inserted into the container (3) applying mechanical pressure.

Fig. 9 illustrates another embodiment of the multiplier (1), in which the plug (2) comprises two blind cavities (2.1, 2.2) to accommodate respective detonators (not shown in the Figure). Fig. 9(a) corresponds to a top view of the stopper (2) and the container (3), while Figs. 9(b-c) are two perspective views in which the notches (3.6) of the mouth (3.2) of the container (3) can be seen, as well as two large lateral grooves (3.7) that extend along the entire length. of the main body (3.1).

Advantageously, the insertion of the detonators is carried out directly on the cap-casing assembly, while the filling and assembly of the casing with the cap is carried out in a factory. Thus, at the foot of the hole, it is only necessary to priming the explosive charge with the detonator(s).

Claims (29)

1. - Multiplier (1) for blasting bulk explosives comprising: - a container (3) adapted to accommodate an explosive charge; and - a cap (2) holding detonators to close said container (3), the cap (2) comprising at least one blind cavity (2.1, 2.2) adapted to accommodate at least one detonator of the multiplier (1); - an explosive charge adapted to be housed in the container (3); where - the container (3) comprises at least one lateral groove (3.4, 3.5, 3.7) adapted to house the cables or tubes of the at least one booster detonator, wherein said at least one lateral groove (3.4, 3.5, 3.7) comprises a or more tabs (3.8) adapted to retain cables or tubes of at least one detonator of the multiplier (1); - the at least one lateral groove (3.4, 3.5, 3.7) is arranged on an external surface of the container (3); and - the container (3) is adapted to cooperate with the stopper (2) housing said stopper (2) inside it. 2. - Multiplier (1) according to claim 1, wherein the container (3) comprises a substantially elongated main body (3.1) defining a longitudinal axis; and a mouth (3.2), located at a first end of the main body (3.1), through which the plug (2) is introduced into said main body (3.1), said mouth (3.2) being adapted to receive the plug. (2) tightly, hermetically closing the container (3). 3. - Multiplier (1) according to any of claims 1 to 2, wherein the container (3) comprises holding means (3.3) configured to cooperate with means of handling the multiplier (1) configured to raise or lower the multiplier in a bore 4. - Multiplier (1) according to the preceding claim, where the fastening means (3.3) are located at a second end of the main body (3.1), longitudinally opposite the first end where the mouth (3.2) of said container ( 3). 5. - Multiplier (1) according to claims 3 or 4 where the holding means (3.3) comprise an opening or handle, and the means of handling the multiplier (1) they comprise: a rope that is adapted to pass through said opening or handle, or alternatively, the tubes or cables of the at least one detonator. 6. - Multiplier (1) according to any of the preceding claims, where the container (3) and the plug (2) act respectively as female and male at the junction of both elements. 7. - Multiplier (1) according to the preceding claim, where in an operative position of said multiplier (1), the plug (2) is fully included in the main body (3.1). 8. - Multiplier (1) according to any of the preceding claims, wherein the plug (2) and the mouth (3.2) of the container (3) comprise one or more recesses and/or protrusions complementary to each other. 9. - Multiplier (1) according to any of the preceding claims, where the union of the container (3) and the plug (2) is carried out by applying mechanical pressure on the plug (2) when introducing it into the main body (3.1). 10. - Multiplier (1) according to any of claims 1 to 8, where the union of the container (3) and the plug (2) is threaded. 11. - Multiplier (1) according to any of the preceding claims, said multiplier (1) being cylindrical or prismatic. 12. - Multiplier (1) according to the preceding claim, said multiplier (1) being a cylinder with a circular and straight base. 13. - Multiplier (1) according to any of the preceding claims, wherein the plug (2) and the container (3) are made of a rigid material. 14. - Multiplier (1) according to the preceding claim, wherein the rigid material comprises plastic, preferably polystyrene and/or polyethylene. 15. - Multiplier (1) according to any of the preceding claims, wherein the container (3) has a length between 15 and 50 cm. 16. - Multiplier (1) according to any of the preceding claims, wherein the space reserved in the container (3) to house the explosive charge has a length of between 10 and 40 cm. 17. - Multiplier (1) according to any of the preceding claims, wherein the diameter of the container is between 40 and 200 mm. 18. - Multiplier (1) according to any of the preceding claims, wherein the lateral grooves (3.4, 3.5, 3.7) of the container (3) have a non-uniform thickness, narrowing as they approach the mouth (3.2). 19. - Booster (1) according to any of the preceding claims, comprising a single blind cavity (2.1) adapted to house a booster detonator. twenty-. Booster (1) according to any of the preceding claims, comprising two blind cavities (2.1, 2.2). 21. - Multiplier (1) according to any of the preceding claims, wherein the lateral grooves (3.4, 3.5, 3.7) are substantially parallel to the longitudinal axis of the container (3). 22. - Multiplier (1) according to any of the preceding claims, wherein the at least one blind cavity (2.1,2.2) has a substantially cylindrical shape. 23. - Multiplier (1) according to any of the preceding claims, wherein the length of the at least one blind cavity (2.1, 2.2) is in the range of 90 to 110 mm. 24. - Multiplier (1) according to any of the preceding claims, wherein the diameter of the at least one blind cavity (2.1,2.2) is not uniform. 25. - Multiplier (1) according to any of the preceding claims, wherein the mouth (3.2) of the container comprises one or more notches (3.6). 26. - Multiplier (1) according to any of the preceding claims, where the Side grooves (3.4, 3.5, 3.7) extend only partly along the length of the container (3). 27. - Multiplier (1) according to any of claims 1 to 25, wherein the lateral grooves (3.4, 3.5, 3.7) extend along the entire length of the container (3). 28. - Multiplier according to any of the preceding claims, wherein the main body (3.1) of the container (3) is cylindrical in shape with its two ends in the form of a truncated cone. 29. - Multiplier set, comprising: - a multiplier (1) according to any of the preceding claims; - at least one detonator configured to be housed in at least one of the blind cavities (2.1,2.2); - Detonator cables or tubes configured to be housed, tightly, in the at least one groove (3.4, 3.5, 3.7) on the side of the container (3).